CN214557708U - Automatic milling head for production of digital control gantry machining center polishing machine - Google Patents

Abstract

The utility model discloses a numerical control gantry machining center smooth machine production self-milling cutter head, which relates to the technical field of engineering machinery numerical control gantry machining and solves the technical problems that the existing numerical control gantry self-milling device only uses a fixed mode fixed size cutter head to perform self-milling, the required cutter head has different sizes due to different machining scenes, and the cutter head is difficult to be applicable to different models when being installed, thereby reducing the working efficiency of the numerical control gantry self-milling device, the numerical control gantry self-milling cutter head comprises a workbench and a numerical control gantry, wherein the numerical control gantry is fixedly installed on the workbench, the utility model discloses a main shaft motor is installed on a traditional bearing box, the main shaft cutter head is installed in a sleeve at the lower end of the traditional bearing box, the main shaft motor is connected with the main shaft cutter head in a synchronous belt rotating mode, when the main shaft cutter head is replaced, the main shaft cutter head only needs to be taken out from the main shaft sleeve for replacement, and then realize the change of cutter head, and then improve numerical control longmen from milling the work efficiency of device.

Description

Automatic milling head for production of digital control gantry machining center polishing machine

Technical Field

The utility model relates to an engineering machine tool numerical control longmen processing technology field specifically is a numerical control longmen machining center ray apparatus production self-milling cutter head.

Background

Along with the development of society and the progress and the improvement of science and technology, people's standard of living is promoted gradually, numerical control processing has become the indispensable operating means in engineering machine tool field, in numerical control longmen machining center's ray apparatus production, need reach through milling the mesa certainly and guarantee the workstation plane degree, the purpose of the perpendicular straightness high accuracy of table surface and main shaft, current numerical control longmen is from milling device and only is carried out from milling by the fixed dimension's of fixed mode milling head, because the processing sight is different, and then make required milling head size different, when the installation milling head, hardly be applicable to on the model of difference, numerical control longmen has been reduced from this and has been milled device's work efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model provides a not enough to prior art, the utility model provides a numerical control longmen machining center smooth machine production is from milling cutter head has solved current numerical control longmen and has milled the device from milling by fixed dimension's cutter head only, because the processing sight is different, and then makes required cutter head size different, when the installation cutter head, on hardly being applicable to different models, has reduced numerical control longmen from milling cutter device's work efficiency's technical problem from this.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: the utility model provides a numerical control longmen machining center ray apparatus production is from milling cutter head, includes workstation and numerical control portal frame, numerical control portal frame fixed mounting is on the workstation, install on the numerical control portal frame removal end and bear the case, be equipped with first mounting hole on bearing the case lateral wall face, it has the support through first mounting hole fixed mounting to bear the case, fixed mounting has spindle motor on the support, fixed mounting has synchronous pulley on the spindle motor drive end, it is equipped with the second mounting hole to bear the case lower wall face, the cartridge has the spindle cutter head in the second mounting hole, be connected through the hold-in range between spindle motor drive end and the spindle cutter head.

Preferably, a spindle sleeve is sleeved outside the second mounting hole at the lower end of the bearing box, and the spindle sleeve is sleeved on the spindle milling head.

Preferably, a motor mounting plate is fixedly mounted between the spindle motor and the support, through holes are formed in the support and the motor mounting plate, and the driving end of the spindle motor penetrates through the through holes.

Preferably, the protection plates are fixedly mounted on the side wall surfaces of the two sides of the support and are of triangular structures.

Preferably, the synchronous pulley and the synchronous belt are both positioned below the support.

Preferably, the front wall and the rear wall of the bearing box are respectively provided with a slideway, and the bearing box is connected with the moving end of the numerical control portal frame in a sliding manner through the slideways.

Advantageous effects

The utility model provides a numerical control longmen machining center smooth machine production is from milling cutter head, it only carries out the self-milling by fixed mode fixed dimension's cutter head to have solved current numerical control longmen from milling device, because the processing sight is different, and then make required cutter head size different, when installing the cutter head, hardly be applicable to on the model of difference, reduced numerical control longmen from milling device's work efficiency's technical problem from this, the utility model discloses an install spindle motor on traditional bearing box, install the main shaft cutter head in the spindle sleeve of traditional bearing box lower extreme, spindle motor is connected through hold-in range pivoted mode with the main shaft cutter head, when changing the main shaft cutter head, only need take out the main shaft cutter head from the spindle sleeve and change, and then realize the change of cutter head, and then improve the work efficiency that numerical control longmen from milling device.

Drawings

Fig. 1 is a schematic view of a main structure of a self-milling cutter head produced by a numerical control gantry machining center optical machine.

Fig. 2 is the utility model discloses a numerical control longmen machining center ray machine production is from the wilmas gear box schematic sectional structure of milling head.

Fig. 3 is the utility model discloses a numerical control longmen machining center ray machine production is from the wilmas gear box spatial structure sketch map of milling head.

Fig. 4 is the utility model discloses a numerical control longmen machining center ray machine production is from the perspective spatial structure sketch map of the vimas gear box of milling head.

In the figure: 1-a spindle motor; 2-motor mounting plate; 3-support; 4-a synchronous pulley; 5-synchronous belt 5; 6-a main shaft sleeve; 7-main shaft milling head; a1-workbench; a2-numerical control portal frame; A3-Wilmacs gearbox.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a numerical control gantry machining center optical machine production self-milling cutter head comprises a workbench A1 and a numerical control gantry A2, wherein the numerical control gantry A2 is fixedly installed on the workbench A1, a bearing box A3 is installed on the moving end of the numerical control gantry A2, a first installation hole is formed in the side wall surface of the bearing box A3, a support 3 is fixedly installed on the bearing box A3 through the first installation hole, a spindle motor 1 is fixedly installed on the support 3, a synchronous belt wheel 4 is fixedly installed on the driving end of the spindle motor 1, a second installation hole is formed in the lower wall surface of the bearing box A3, a spindle cutter head 7 is inserted into the second installation hole, the driving end of the spindle motor 1 is connected with the spindle cutter head 7 through a synchronous belt 5, a spindle sleeve 6 is sleeved outside the second installation hole at the lower end of the bearing box A3, the spindle sleeve 6 is sleeved on the spindle cutter head 7, a motor installation plate 2 is fixedly installed between the spindle motor 1 and the support 3, the through-hole has all been seted up on support 3 and the motor mounting panel 2, the through-hole is run through to 1 drive end of spindle motor, fixed mounting has the guard plate on the 3 both sides wall face of support, the guard plate is the triangle-shaped structure, synchronous pulley 4 and hold-in range 5 all are located support 3 below, install the slide on the wall around the bearing box A3 respectively, bearing box A3 removes end sliding connection through slide and numerical control portal frame A2.

The detailed connection means is a technique known in the art, and the following mainly describes the working principle and process, and the specific operation is as follows.

Example (b): as can be seen from the figures in the specification, in use, the support 2 is fixedly mounted on the bearing box A3 through the first mounting hole on the bearing box A3, and a spindle motor 1 is fixedly arranged on the support 2 through a motor mounting plate 2, the driving end of the spindle motor 1 penetrates through a through hole, and a synchronous pulley 4 is installed, a main shaft milling head 7 is inserted into the bearing box A3 through a second mounting hole at the lower end of the bearing box A3, the main shaft milling head 7 is fixed through a main shaft sleeve 6, the synchronous pulley 4 is connected with the main shaft milling head 7 through a synchronous belt 5, when the driving end of the spindle motor 1 rotates, the driving end of the spindle motor 1 rotates at the movable synchronous pulley 4, the synchronous pulley 4 drives the spindle milling head 7 to rotate through the synchronous belt 5, and further, the main shaft milling head 7 mills a workpiece on the workbench, and when the main shaft milling head 7 is replaced, the main shaft milling head 7 is only required to be taken out from the fixed main shaft sleeve 6 for replacement.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions.

Claims (6)

1. A numerical control gantry machining center optical machine produced self-milling cutter head comprises a workbench (A1) and a numerical control gantry (A2), wherein the numerical control gantry (A2) is fixedly arranged on the workbench (A1), it is characterized in that a bearing box (A3) is arranged on the moving end of the numerical control portal frame (A2), a first mounting hole is arranged on the side wall surface of the bearing box (A3), a support (3) is fixedly mounted on the bearing box (A3) through the first mounting hole, a main shaft motor (1) is fixedly arranged on the support (3), a synchronous belt wheel (4) is fixedly arranged on the driving end of the main shaft motor (1), a second mounting hole is arranged on the lower wall surface of the bearing box (A3), a main shaft milling head (7) is inserted into the second mounting hole, the driving end of the spindle motor (1) is connected with the spindle milling head (7) through a synchronous belt (5).

2. The numerical control gantry machining center bare engine production self-milling head as claimed in claim 1, wherein a spindle sleeve (6) is sleeved outside a second mounting hole at the lower end of the bearing box (A3), and the spindle sleeve (6) is sleeved on the spindle milling head (7).

3. The numerical control gantry machining center bare engine production self-milling head as claimed in claim 1, wherein a motor mounting plate (2) is fixedly mounted between the spindle motor (1) and the support (3), the support (3) and the motor mounting plate (2) are both provided with through holes, and a driving end of the spindle motor (1) penetrates through the through holes.

4. The numerical control gantry machining center bare engine production self-milling head as claimed in claim 1, wherein protection plates are fixedly mounted on two side wall surfaces of the support (3), and the protection plates are triangular in structure.

5. A numerical control gantry machining center photo-machine produced self-milling head according to claim 1, characterized in that the synchronous pulley (4) and the synchronous belt (5) are located below the support (3).

6. The numerical control gantry machining center bare engine self-milling head as claimed in claim 1, wherein the front and rear wall surfaces of the carrying box (A3) are respectively provided with a slideway, and the carrying box (A3) is slidably connected with the moving end of the numerical control gantry (A2) through the slideway.

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